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(Sheets-Sheet 1. H.- W ADAMS. Q Iurn ac e'and Apparatus for Smelting Ores and flondens ing Fumes.-

No; 227,110. Patents I 8,1880.

H, W, ADA 4Sheets-Sheet3,

Ffirnaoe and Apparatus for Smelting Ores and Condensing Fumes.

No. 227,710. so.

NPETERS. PHQTO-UTHOGRAPH R. WASHINGTON. D O.

- 1 Wz ir zamas.

H. W. AD"AM S, whens-sheen, Furnace and Apparatus for Smelting 0res.a.nd

Condensing Fumes.

No. 227,710. I Pgtented May 18. 1880;

' Inveizhr- 1 i -I I I UNITED STATES PATE T OFFICE/O HENRY W. ADAMS, OF NEW YORK, N. Y.

.FURNACE AND APPARATUS FOR SMELTING ORES AND CONDENSING FUMES.

SPECIFICATION forming part of Letters Patent No 227,710, dated May 18, 1880.

Application filed January 27, 1880.

To all whom it may concern Be it known that I, HENRY WV. ADAMS, a citizen of the United States, residing in the city, county, and State of New York, have invented a new, useful, and Improved Furnace and Apparatus for Smelting Metallic Ores and Saving their Products; and I do hereby declare that the following is a full, clear,- and exact description of the invention, which will enable others skilled in the art to which it appertains to make and use the same.

My invention relates to improvements in blast-furnaces and apparatus for smelting metallic ores and saving their products; and the objects of my improvements are to produce a better hot-blast and more intense heat, in order to inelt the ores into a thinner and more limpid slag, so that all the metal contained in it may easily settle from it and be saved to inclose underneath the bottom of my furnace a cast-iron pot to be. lined with any infusible substance and protected by fire-bricks from a melting heat, so as to prevent the leakage and loss of the fused metal in the base of the furnace; to keep this pot sufficiently hot by a special fire underneath it to prevent the melted metal from chilling in the same; to provide a bench of rctorts to be heated by the hot gases which escape from the furnace for the manufacture of chlorine gas or muriatic-acid gas for use in the treatment of non-smelting ores; to provide a condenser for condensing all the metallic vapors and fumes which escape from the furnace, and saving the same; to manufacture chlorinewatcr and muriatic acid; to manufacture sulphuric acid from the sulph urous-acid gas which escapes from the furnace, for use in decomposing the chloride of sodium charged into the before-mentioned retorts' for the generation of muriatic-aeid gas or of chlorine gas when the said retorts are charged with a proper percentage of the oxide of manganese in conjunction with common salt.

I attain these objects by the mechanism illustrated in the accompanying drawings, in which Figure 1 is a front perspective of the entire machine; Fig. 2, a rear perspective of the machine; Fig. 3, a longitudinal section Fig. 4, a detailed view of the bottom of the furnace in a vertical section; Fig. 5, a detailed sectional from the furnace charged with metallic sulphides, nitric acid, which comes from the nitrate-of-soda furnace, steam from a steamboiler, and atmospheric air, which four elements are necessary to produce sulphuric acid; Fig. 7, a longitudinal section of the machine for saturating water with chlorine gas or muriatic-acid gas and a tank for receiving and storing the same; Fig. 8, a cross-section of the machine for saturating water with chlorine gas or with muriatic-acid gas when either the one or the other is generated in the beforementioned retorts. Fig. 9 is a detailed vertical section of a series of iron pipes arranged in a circular form between the outer and inner walls of the furnace, where they are highly heated, and through which atmospheric air is forced by a blower or other power, to escape into the ash-pits and over the furnace-fires of the furnace Fig. 10, a detailed section of the lower furnace and its flue.

Similar letters refer to similar parts throughout the several views.

A represents the platform on which the furnace and apparatus are erected. B is the lower fnrnace-dooryO, the fire-place; D, the grate-bars E, the ash-pit F, the flue, and G the uptake. This furnace is constructed in the platform A, and extends underneath and across the diameter of the base of the smelt ing-furnace. It should be sixteen inches wide and eighteen inches from the grate-bars to the crown of the arch. The ash-pit should be sixteen inches wide and two feet deep and twothirds of the diameter of the smelting-furnace in length. These proportions are best for the proper effect of the hot-air blast, which is introduced both into the ash-pit and over the furnace-fire, for the purpose of keeping the base of the smelting furnace above it sufciently hot to prevent either the melted metal or slag from chilling in the lower end of the said furnace and destroying its usefulness.

H is the door of the smelting-furnace; I, the fire-place; J, the grate-bars; K, the ash-pit. This fire place is twelve inches wide and sixteen inches high from the top of the gratebars to the crown of the arch, and four feet long from its front end to its opening into the furnace. The grate-bars are three feet long, and the distance from the front side of the bridge-wall to the interior of the furnace is twelve inches. The bridge-wall is four inches high above the grate-bars. These are the most suitable proportions to create the proper heat needed by means of the hot-blast produced by the heated air injected over the burning fuel and into the ash-pit of the furnace. The ash-pit is three feet long, one foot wide, and eighteen inches deep.

I have shown only one furnace. Any 'desired number may be employed. I usually use four, placed equally distant and on a level with each other. Anynumber of tuyeres may be employed underneath and between the mouths of these fire-places, which open into the furnace, to inject jets of air under pressure into the furnace, to aid the fusion of the charge, as is customary in iron blast-furnaces. Eight of these is a good number, having nozzles about one inch in diameter.

L is the outer circular wall of the smeltingfurnace. It is thirteen inches thick, and constructed of common bricks laid with good mortar. It is about eleven feet in external diameter from its bottom to its top. It is about twenty-five feet high from the platform to the feeding-door.-

M is a platform about sixteen feet long and six feet wide, on which the ore to be fed into the furnace is dumped. The furnace is supposed to be built on the side of a mountain, so that a cartway on a level with this platform may be made on the ground sufficiently broad to enable carts to come and go and dump their charges without inconvenience.

N is an arched flue over the top of the furnace for conducting the gases, as hereinafter described. The walled arch and its two ends are constructed of bricks laid in good mortar, and are all about two feet thick, so as to be gas-tight. The inside capacity of this fine should be at least five feet, wide and eighteen inches high.

is the feeding-door, which is about eighteen inches long and one foot wide. This door opens a passage, through which the ore is pushed into the furnace.

P is a tap-hole for drawing off the melted metal from the bottom of the smelting-furnace.

Q is another tap-hole, a little higher up, for drawing off the fluid slag. The tap-hole P should be inserted into the crucible close to the bottom, so as to draw the metal out clean. The tap-hole Q'should be inserted into the crucible about eighteen inches above its bot tom. The former-should be at least two inches in diameter and the latter six inches. These two tap-holes should always be made into the cruciblc,for special uses for drawing off clean both'the metal and slag when required, even though other similar tap-holes should be made and fitted with overflow-pipes having their discharging ends so elevated as to run off the metal and slag-continuously. I

R is the blast-pipe, which conducts the hot air under pressure over the furnacc-fire.

S is a stop-cock for regulating the blast.

T is the inside wall of the furnace. constructed of good fire-bricks laid in fire-clay mortar. It is thirteen inches thick and as high as the outside wall. 1t is circular, like the outside wall, and five feet in internal diameter at its top. This internal diameter of five feet extends downward for a distance of twelve feet, and forms the cone of the furnace. From this point the boshes commence and extend down five feet, gradually narrowing to a diameter of three feet. Below this point is the breast of the furnace, three feet deep and three feet wide. Below this again is the crucible, which is four feet deep, three feet in internal diameter at its top, and narrowing gradually to one foot in internal diameter at its bottom.

Uis this cast-iron vessel. It has a thickness of about two inches, and internal dimensions, when the lining is put into it, as aforesaid. This rests on a floor of fire-bricks about five inches thick. This floor is represented by 'V. It forms the top of the fire-place beneath it, so that the heat from the furnace below may heat it red-hot, and consequently heat the iron pot sufficiently hot to prevent the liquid metal and slag contained in it from chillin It is otherwise bricked in, so as to prevent it from meltin W is a lining about one inch thick, composed of plumbago, alumina, oracasing composed of the infusible carbon deposited on the inside of coal-gas retorts. These materials, or any of them, or any other suitable material, may be pulverized and mixed with molasses or any other suitable adhesive substance into a very stiff dough, and pressed into its place with proper machinery and suitable mechanical power. The iron pot is designed to prevent any leakage of fluid metal or slag through the base of the furnace, and the lining is designed to protect it from too great heat and prevent any adhesion of fused matter to it. Thisiron pot is also intended to conduct more readily than bricks or tiles could the heat from the furnace underneath it up around the sides and near the top of the receptacle of the metal and slag, for the purposes already explained. The tap-holes are castin this pot, as shown in the detailed view of Fig. 4. Y

I prefer for general use the construction of the furnace as here shown in detail. Its fireplace is inclined downward at quite an angle. This is for two reasons-first, to prevent the ore from falling into the fire-place, and, secondly, to prevent the fluid slag from readily overflowing the bridgewall.

X and Y are pans in the two ash-pits, for holding water to be evaporated by the heat deflected from the tires above them and supply aqueous vapor to cool the grate-bars, and

Itis

into oxygen and hydrogen gases for the production of more intense and abundant combustion.

The annular space E between the outer and inner circular walls, L T, of the smelting-furnaceisonefoot wide. This spaceis provided for two purposesfirst, that it may be filled with sand, ground slag, or other suitablesubstance packed tightly to prevent the escape of noxious gases through the cracks or joints of the inner wall, and, secondly, for theintroduction of iron pipes, to be highly heated, through which atmospheric air may be forced by suitable machinery, to be introduced as a hot-blast into the ash pits and over the burning fuel of the furnace. These pipes are shown in Fig. 9. They are three-inches in diameter, more or less.

R is the end of the pipe, which enters the combustion-chamber of the upper fire-place just over the furnace'door, and delivers a blast of hot air into the said chamber. This blast produces a blow pipe heat and forces the white-hot products of combustion into contact b is a stop-cock for regulating this blast.

with the red-hot and roasted orein the smeltin gfurnace. S is the stop-cock for regulating the force of the blast. This pipe passes up and down from the bottom to the top of the aforesaid annular space, each bend being about a foot apart, until the circle is completed, and the opposite end comes down near to the two fireplaces and ash-pits, from whence it starts. a represents a branch from this pipe, which enters the side of the upper ash-pit for supplying it with hot air under pressure," to be forced up through the grate-bars and through the burning fuel to intensify the combustion.

01s another branch pipe, entering the combustionchamber of the lower fire-place immediately over the furnace-door, to deliver ablastof hot air into it for the purposes already mentioned. cl is the stop-cock to control this blast. c is the final end of the first-named pipe, and enters the ash-pit of the lower fire-place to inject a blast of heated air for purposes similar to those described. f is the stop-cock to regulate the same. To force atmospheric air throu gh this bent pipe, and to cause it to be discharged at the same time at both ends of the same, the pipe g is extended up to the T h and screwed into the said T. The blower Z is then attached to the pipe 9.

A belt is attached to the pulley t, and made, by means of any suitable power, to revolve rapidly the winged shaft of the blower Z, which forces air into the pipe 9 and up into the T h, from whence it goes both ways and supplies the respective blast-nozzles.

This arrangement for heating the air to a very high temperature by means of the waste heat of my smelting-furnace 1 consider to be very simple, economical, and effectual.

The force of the blast should be equal to from five to ten pounds per squareinch. The latter pressure is'necessary in all regions of high elevation, where the air is too rare'to produce. intense combustion without considerable compression. In such cases a cylinder-blower fitted'with-a piston and driven by an engine must be used.

I build the inner circular wall of my smelting-furuace first. I then set up the air-blast pipes around it to within one footof the top of the said wall, and at such a distance from it that the centers of all the said pipes shall be six inches from the outside surface of the wall. I then commence to build the outer circular wall, leavinga space one foot wide between the two walls. After building it up one or two feet high, I then fill up this empty space with sand or ground slag or other suitable pulverulent matter, and ram it down tightly. 1

This leaves the iron air-pipes in the center of the space between the two walls surrounded firmly by the said packing. I then build up another section, and fill it up as before, until the outer wall is carried up to the same height of the inner one. I then fill in the empty space between the two walls and above the tops of the pipes with solid brick-work, which is represented by the letter j.

In is a bench of three retorts, l m a, each about two feet wide, thirty inches high, and seven feet long. Both ends project through the sides of the bench. The front ends are pro; vided with doors and fastenin gs similar to coal-gas retorts. The front end of each retort is furnished with an inlet-pipe, 0 0 0, and a stop-cock, 1911p, and a funnel, (Lq q, for the introduction of sulphuric acid. They should be made of stoutlead or clay. The retorts should be made of well burned fire-clay and provided with earthen .or iron retorts, fitting loose-1y inside, to be replaced when injured by sulphuric acid, chlorine gas, or muriatic=acid gas. They are to be used as hereinafter de scribed. They are set in this place, so as to be heated by the hot gases escaping from the blastfurnace without the expenseof a separate fire.

The bench 7c and thewater-tank 2 rest on the foundation 8 and piers r. This foundation is about forty feet long and five feet four inches high. It consists, in the first place, of two brick walls eighteen inches thick and having the aforesaid length and height, standing directly opposite to each other and six feet apart. The rear wall has no openings through it. The front wall has eight openings, which are closed by the doors tttttttt.

The letter a is a pier built of brick, two feet wide and twelve feet high, between the two outside walls and in close contact with them, and rising six feet eight inches above them. An empty space about seven inches wide is left through the center of the upper six feet, eight inches of this partition to be filled with sand or ground slag or other suitable material, and packed tightly to prevent the escape of any noxious gases through any cracks orjoints which the heat might make in this wall. The side walls are carried up eighteen inches thick above the foundation 8, to the height of eight feet and eight inches. These two side walls make the front and rear sides of the bench is,

and extend to theouterfurnace-wall, L. When these two outside walls are built the partition v is built up with them to the same height. An arched opening is left in the lower end for the gases coming from the furnace to pass through into the bench it, under the retorts l m 7%, and heating them on theirwayto the exit-flue. This partition causes the gases in the furnace to descend under the retorts for the purposes aforesaid. The thickness of this partition is about thirteen inches, and the top of it is distant from the outside wall of the furnace two feet and eight inches, leaving that width of space for the flue.

w is an arched covering ten feet long, three feet thick, and nine feet wide. On this arch rests the arch x, which is three feet thick and nine feet wide, resting by its other end on the top of the two opposite walls of the smeltingfurnace. Two side walls, y y, are now built up underneath this arch, and rest on the top of the furnace and on the tops of the two side walls of the bench 75, so as to close up the flue N.

The letter z is a water tank twenty feet long, five feet deep, and nine feet wide. It is made of thick plank and lined with sheet-lead. It is designed to hold water for cooling the hot gases and metallic fumes generated in the smelting-furnace and passing from it through the flue N, and through the bench 7t, and through the flue t6.

The letter I) is a pipe for delivering cold water into the bottom of this water-tank at the end farthest removed from the furnace. c is an overflow-pipe, placed in the opposite end of the tank and near its top. These pipes should be from two to three inches in diameter. The object of these pipes is to deliver cold water into the first-named end of the tank, and to discharge the hot water from its opposite end, for the purposes aforesaid.

The fine extending from the bench k and running into and through the water-tank is madeas follows: The material employed is sheet-lead, from one-quarter to one-half of an inch thick, and five feet wide. The exterior portion or covering of the flue is shown by d. The lower side of the line is shown by c. The distance between the upper and lower sides of the flue is one foot. Its mouth widens to two feet at its point of junction with the brick flue opening from the bench 7c. The two opposite sides of this flue are represented by f.

The bottom ends of both the upper and under sides of the flue are soldered fast to the bottom of the water-tan k. Spaces are cut through the bottom of the water-tank, one foot wide and five feet long, (shown by the letter g,) which spaces are continuations of the flue below the This arrangement pro- The spaces by the funnel-shaped boxes h, as shown in i Fig. 3. These, too, are made of heavy sheetlead and soldered fast to the bottom of the tank. They are five feet long and extend two feet below the bottom of the tank. They are provided with ends soldered fast to the two sides of each box, so as to make a continuous flue, as shown by the arrows aforesaid. These funnelshaped boxes are designed to receive the condensed metallic vapors and fumes, which are carried over from the smelting-furnace and borne along through the flue by the gases passing along to the chimney. The opening made in the lower end of these boxes by the two approaching sides of each is eight inches wide and five feet long. Each of these openings is closed by a sliding door, vi, which is made to move easily forward and backward in grooves made in the sides of each box near their lower extremity. A slot corresponding in width and thickness to these sliding doors is cut through the side of the wall 8 directly opposite to and parallel with the grooves in the boxes, so that these sliding doors may project through these slots far enough to be taken hold of by the hand, and be drawn out and shoved back again by a workman on the outside. The ends of these sliding doors are seen in Fig. 1 projecting through the wall .9, as indicated by the letter j.

The letter 1" represents piers built of brick, on which the bottom of the water-tank z rests. These piers are thirteen inches wide, six feet long, and five feet four inches high. The wall 3 is built up to the bottom of the water-tank and fitted snugly to the ends of the aforesaid piers. A similar wall is built on the opposite side, as shown in Fig. 2. This arrangement divides the space under the water-tank 1' into six equal chambers.

into these separate chambers. These doors are two feet eight inches long and two feet They cover openings through the wall The doors t tt t t it open 1 metallic fumes and matters which collect in the bottom of the bench is and underneath the funnel-shaped boxes m m, which are provided with sliding doors, in the manner before described. Their outside projecting ends are indicated by a it. Their object and use are similar to those already described.

Ihave now traced a continuous flue from the roasting ore through N to the pipe 0, which passes through the extreme end of the watertank z and enters the sulphuric-acid chamber 10, which should be twenty feet long, ten feet wide, and ten feet deep. This chamber is to be lined with heavy sheet-lead. It should be half an inch thick and all the joints thoroughly united with pure lead. On the top of this chamber, and at its extreme en d, is placed the uptake g. This is the termination of the flue between the roasting ore and the outside air. This chimney should be about eighteen inches in diameter and ten feet high. 1" is a steampipe, which enters it and turns its open end upward perpendicularly. s is a stop-cock for regulating the amount of steam allowed to escape from the pipe 1" and produce an upward draft through the uptake q.

The uncondensed gases which escape from the roasting ores in the blast-furnace, and which enter this sulphuricacid chamber, will be very largely composed of sulphurous-acid gas, generated from the burning sulphur in the roasting ore. My object is now to convert this sulphurous-acid gas into sulphuric acid, to be used chiefly in the decomposition of the chloride of sodium in the retorts which are set in the bench It. In these retorts I manufacture either chlorine gas from chloride ofsodiu m,the oxideof manganese, and sulphuric acid, to be employed as a solvent of gold in the non-smelting ores; or I manufacture muriatic-acid gas from chloride of sodium and sulphuric acid, to be used in some of the metallurgical steps which I take in the treatment of some ores, and which are not necessary here to describe; but in both casesI need a large amount of sulphuric acid. This I propose to make as follows:

Itis necessary to mingle together four elements in order to produce sulphuric acid: sulphurousacid gas, nitric-acid gas, aqueous vapor, and atmospheric air. This I do in the sulphuric-acid chamber 1) in the following manner: The sulphurous-acid gas is delivered into the chamber through the pipe 0 from the roasting ores in the si'n'eltirig-furnace, as aforesaid. The nitric-acid vapor is delivered from the retort it through the pipe to into the pipe 1), and near its elbow, which is inserted into the pipe 0, and which opens toward the sulphuric-acid chamber 19. The end of r, through which the pipe to isinserted, is made gas-tight around the pipe to, leaving a chamber between the inserted end of a and the inside of the larger pipe o", as in the detailed view shown by Fig. 6.

w is a steam-pipe, which passes through the pipe 2:, and through another pipe, m, which surrounds the pipe to, and which is made steam-tight with it in such a manner as to leave a small annular chamber between a and .00, into which the inserted end of the steampipew' enters. y is a stop-cock on the steampipe 24%. I i

The letter 2 is an air-pipe inserted into the pipe o, and provided with a stopcock. By opening the stop-cock in z and opening the stop-cock in y, steam passes through the pipe w into the annular chamber between a and m, and, escaping in an annular and expanding jet, impinges against the inside of the pipe 12, and makes a partial vacuum behind it in the chamber between o andm and o and a, which draws in atmospheric air through the pipe 2, which mixes in the elbow of o with the steam and the nitric-acid vapor discharged from a, from whence these three elements pass into 0, and mix with the sulphurous-acid gas which comes from the roasting sulphides, and enter the chamber 1) together.

The nitric-acid vapor furnishes oxygen to oxidize the sulphurous-acid gas, and the oxygen of the air restores to the nitric oxide the equivalent of oxygen which it carries to the sulph'urous-acid gas, and the aqueous vapor furnishes the needed humidity to dissolve the crystalline atoms of sulphuric acid thus manufactured, and liquefies it, and causes it to trickle down in a diluted fluid state to the floor of the chamber 19, from whence it may be drawn off through the pipe a".

The letter I) is a furnace provided with an iron retort, t, for distilling nitrate of soda and sulphuric acid and generating nitric-acid vapor to supply the pipe a, as aforesaid.

A detailed view of the furnace is shown in Fig. 5.

The retort t is filled about halffull with nitrate of soda. About an equal weight of sulphuric acid is added to it for one charge. A fire is put into the furnace, and the retort is heated moderately at first and more highly at the latter part of the distillation. The residuum in the retort Will be sulphate of soda.

In Fig. 7, 0 is a round foundation, built of brick, seven feet high and six feet in diameter. On it stands the vessel d constructed of wooden staves two inches thick and hooped with strong iron hoops. It is six feetin diameter and six feet high, and has strong heads in both ends. 6 f and g are strong wooden boxes, placed one above the other within this vessel. 1& is a pipe, about one inch and a half in diameter, passing through the upper head and extending a little distance below its under surface. '6 is its stop-cock. j is a funnel fastened to its upper end. It is a pipe about an inch and a half in internal diameter and provided with a stop-cock, The letter m is a support for the pipe r A cross-section of this vessel shows more clearly the arrangement of the boxesinside of this vessel and the various pipes connected with them. It will be seen that these boxes are placed one above the other, somewhat like a pair of stairs. The object in view is to completely saturate water with chlorine gas or with niuriatic-acid gas, as the case may be,

which I generate in the three retorts setin the leakage.

through its bottom, and having its upper end lower than the top of the box, the object being to allow the water in the box to Overflow through this pipe into the box f underneath it. The box f is provided with a similar pipe, 0 to allow the same water to pass into 9 below it, where it overflows the vessel g into the reservoir (7?.

The letter p is a pipe communicating with the back end of the top retort in the bench is, and passing through the top of the reservoir d and terminating a little above the bottom of the box 0 The cold water let in through the pipe k into the funnel j passes through the pipe ]L2, and fills the box 0 up to a level with the top of the pipe n when it overflows through that pipe into the box underneath. At the same time the chlorine gas or the muriatic-acid gas, as the case maybe, which flows from the top retort through the pipe 19 escapes from the end which is submerged beneath the water in the box 6 and is absorbed. by it. The water thus partially charged with the gas passes down into the box f where it receives another fresh quantity of gas through the pipe leading from the retort m. This same water, now more perfectly saturated, passes down through the 'pipe 0 into the box 9 where it is again charged with a fresh supply of gas flowing through the pipe 1*, leading from the retort n. The water thus completely saturated and overflowing into the vessel (1 escapes through the pipe .9 into the storagetank F. This tank is made of solid planks, inclosed in a hard-wood frame and wedged to gether tightly, so as to effectually prevent It is provided withatight top. The pipe 8 dips down to near the bottom of this tank. The pipe a provided with a stop-cock, passes through the top simply,and is designed to allow the air to escape from the tank when it is being filled with water. The pipe '0 provided with a stop-cock, passes through the top of the tank and down to near its bottom, its

object being to allow a pump to be attached to its top by a suitable connection to deliver the'water in the tank t back again into the funnel j to pass through the boxes 0 f and g again, and be more completely saturated with the gas or gases aforesaid.

- The pipe 20 is designed to indicate when the tank t is full. The pipe x is designed to draw off the saturated water in 1?.

This device is believed by-me to be new and useful for saturating water completely with the gases aforesaid. The gases thus manufactured and the water thus saturated with them are employed by me in the extraction of the precious metals from certain non-smelting ores in a very economical and remarkable mannor, to be more fully set forth in another ap- -for smelting metallic ores and saving their products, I will now explain the operation of my invention:

All metallic ores, of every name and sort, which are capable of being melted to a fluid slag either by themselves or by mixing one-or more with others, or by the aid of suitable fluxes, can be smelted in my furnace. In general, all ores to be smelted must first be broken up into sizes similar to those of hickorynuts or hens eggs. The pre .)arations, mixtures, and fluxes of these smelting ores require much skill. As, however, I intend to make another application for Letters Patentcovering this branch of the metallurgical art, I shall not enter into a particular description of the same in this specification.

To put my furnace into operation, I first du mp on the platform M a suitable quantity of prepared ore for charging the furnace. I then open the door 0 and push through it a sufficient quantity of ore to fill the furnace full, as shown in Fig. 3, and close the door. I then put fuel into the fire-places C and I and ignite it. I fill the two pans X and Y in the ashpits with water and close the doors tightly. I then start the engine and put the blower Z in rapid motion. Being connected to the pipe g, air is forced through this pipe up to the T It, from whence it divides and flows each way through the bends of the heating pipe, as shown in Fig. 9. By opening the stop-cock S in R a powerful blast of air is delivered into the fire-place I over the fuel, which intensities the combustion and forces its hot products over the bridge-wall and into the ore to be melted. I also openthe stop-cocks b d f in the other end of the blast-pipe It, and deliver blasts of air into the fire-place 0 above the fuel, and into its ash-pit E, and into the ash-pit K. The pressure of air in these ash-pits causes it to ascend through the grate-bars and through the burning fuel and create additional heat, and incandescent gases to be driven with a blow-pipe intensity from the mouth of the upper furnace into the melting ore, and from the lower fire-place, under the floor V, through the flue F, to the uptake G. The blast into the fire-place and ash-pit O and E need not be very strong. The consequences noware, that the floor V and the cast-iron pot U very soon become heated nearly or quite red-hot. No danger can now occur that the melted metal or slag filling the pot U will chill. The ore under the operation of theintense heat begins to melt into a very fluid slag. The metal in it, being also melted and having a specific graw ity greater than the slag, will settle from it and collect in the bottom of the pot U. It is of the utmost importance that the heat shall be sufficiently intense to fuse the ore into a very thin and limpid slag; otherwise the metal cannot subside from it, but will run oil in the' slag.

One of the great merits of my improved furnace and powerful hot-blast is, that I fuse the ore so perfectly that every particle of metal separates from the liquid slag. The hot gases now rise up through the interstitial spaces of the charge and raise it to a red heat. This effects a perfect roasting of the ore by the time each successive layer settles down to the melting-point opposite the mouth of the fire-place I.

As the heat increases the inside wall of the furnace T becomes red-hot, and the sand packing between this wall and the outside wall, L, rises to a very elevated temperature, and communicates a high degree of heat to the entire length of the blastpipe It, and consequently to the air passing through it. By this arrangement this iron pipe is protected from the direct action of the fire and corrodiug gas. It takes up a large portion of the waste heat, which would otherwise escape through the outer wall, L, and delivers it back again into the furnace-fires, thereby saving in uch fuel and adding to the force of the blast. This packing also makes the wall L gas-tight.

The sulphur in the sulphides composing many of the ores is volatilized by the heat, and takes tire if sufficient oxygen be present, and produces sulphurous-acid gas. The water in the pans in the two ash-pits boils by the deflected heat, and the steam rises up through the grate-bars, cooling them in its passage, and enters the fuel above them, where it is decomposed into oxygen and hydrogen gases, which add fuel to the fires and w hite-hot gases to the smelting-furnace. Along with the ascending gases aforesaid, metallic fumes of the more Volatile metals are borne, in greater or less abundance, and all the mingled products of combustion pass up and through the arched flue N, and down under the retorts Zm n in the bench 7t, and up between and around the said retorts, and escape through the flue a in the direction of the arrows to the uptake q. In the passage of the incondensaole gases from the furnace to the chimney aforesaid all condensable matters are eliminated from them. Such as fall by cooling and by greater specific gravity from the flue N and from the interior of the bench 7t collect in the funnel-shaped boxes m m. The rest pass into the flue a, and are condensed successively as they are cooled in the different parts of this flue, which is submerged in the water-tank z.

All the metallic products which are thus condensed and which fall by cooling and by specific gravity are collected in the funnel-shaped boxes h h h h h h. ,The character and quan tity of these condensed products will depend on the character of the ore charged into the blastfurnace; but as the furnace and every part of the apparatus are gas-tight, no leakage or loss of any metallic vapors or fumes can occur, and whatever sort or quantity comes from the furnace will be found condensed in some one of these boxes.

A considerable separation of the different metals and powders will be thus secured, in consequence of the different melting-points and different specific gravities of these substances. The accumulations in these several boxes aforesaid may be removed from time to time by taking hold of the ends j of the slidin g doors 2" of the boxes under the water-tank and of the ends at n of the sliding doors under the retorts, and drawing them out and allowing the condensed products to fall into the trays k k 7c 7t 7t 7t and into the trays l l, and then pushing the doors respectively hack into their places and opening the doors t and drawing out the trays 7t and Z, and emptying them and returning them to their places and closing the said doors and lutin g their joints with clay. These condensed products are to be treated and utilized according to their character. The cooled and permanent gases pass from the fine a through the pipe 0 into the sulphuric-acid chamber 1). A considerable portion of these gases is sulphurous acid. I convert this into sulphuric acid in this chamber in the manner hereinbefore described. To delay the rapid passage of the mixed sulphurous acid, aqueous vapor, nitric acid vapor, and atmospheric air, and give them more time for mutual reaction in this chamber, I arrange unutilized gases escape through the uptake q.

The letter 1' is a steam-pipe provided with a stopcock, by opening which a jet of steam shoots up into q and produces a draft, which may be regulated according to circumstances.

The strength-of the sulphuric acid made by this process in the chamber 19 will be about 1.65 gravity. This is strong enough for my purposes without further concentration in platinum stills. manufacture of chlorine gas, for dissolving gold, and muriatic-acid gas, I charge each of the retorts Z m n with two hundred and fifty pounds of chloride of sodium and three hundred and thirty pounds of sulphuric acid from the chamber and three hundred pounds of the deutoxide of manganese. I first mix well together the chloride of sodium and manganese in these proportions before charging. After charging the retorts with this mixture in the proportions aforesaid, and shutting up the doors gas-tight, I introduce the sulphuric acid through the funnels q q q. The retorts are sufiiciently heated by the gases from the smelting-furnace, as aforesaid. A double decomposition takes place between the substances in the retort. Water is decomposed into oxygen and hydrogen gases. The oxygen unites with the sodium of the salt and converts it into an oxide. The sulphuric acid dissolves it and converts it into the sulphate of soda. The hydrogen of the water combines with the oxygen of the manganese and reproduces water. Chlorine gas is set free, and passes through the pipes 13 (1 and "r into the boxes 0 f and g of the vessel 61 At the same time water is let into these boxes throughthe pipe W from the funnel 9' and from the supply-pipe R The water thus saturated with chlorine gas and overflowing To utilize this acid for the manufacturing chlorine gas, with the exception ofthe deutoxide of manganese. This substance is not necessary in this operation. Muriatic-acid gas is thus generated in the retorts. The water is decomposed into oxygen and hydrogen. The oxygen unites with the sodium of the salt and converts it into an oxide. The sulphuric acid dissolves it and converts it into the sulphate of soda. The hydrogen of the water, in a nascent state, unites with the chlorine and produces muriatic-acid gas, which is a compound of one volume of chlorine and one of hydrogen united without condensation. The muriatic-acid gas thus generated in the r etorts passes out of them through the pipes aforesaid and into the boxes charged with water, as aforesaid. The water absorbs, at a temperature of 69 four hundred and sixty-four times its volume, increases onethird in bulk and about three-fourths in weight. This acid flows through the pipe 8 into the storage-tank't for further use. Sulphate of soda is left in the retorts as a secondar Y product. As the charge of ore in the blast-furnace melts at its lower extremity, op-

posite to the mouth of the fire-place I, the

metal collects at the bottom of the pot U, and the slag, being lighter in gravity, rests on it,

- while the ore above gradually settles down.

As this takes place fresh ore is pushed into the top of the furnace from the platform M through the door 0, so as to keep the furnace full of ore up to its top. The door 0 is kept closed. The fluid slag below the umnelted ore and above the melted metal is drawn off through the pipe Q. The melted metal collected in the bottom of the pot U is withdrawn through the pipe P.

It will be seen in the detailed view of Fig. 4 that A shows a large opening into the side of the furnace-wall opposite these tap-holes and above the floor V, for the purpose of opening and closing these tap-holes in closer proximity to the pot U. They are closed by a ball of stiff clay pushed into their months by an iron rod, one end of which has a diameter nearly as great as the diameter of the holes. They are opened by the other end of this rod, which is sharpened to a point, so as to pierce through these clay stoppers.

The fluid slag is always to be drawn off first through the pipe Q. As it flows out the charge in the furnace settles down. When it ceases to flow this tup-hole'is closed up, as aforesaid. Then the lower pipe, P, is opened, and the metal flows through it from the bottom of the pot U. hen this ceases to run metal the hole is closed. The slag is conducted away by a descending gutter. The times of opening and closing these tap-holes will depend upon the quantity of ore melted in a given time and the quantity of metal contained in the ore.

perience alone can determine them.

If it should be desired to have the slag and metal flow continuously from these respective f tap-holes, the pipes P and Q may beinclined upward to a suitable height, so that the fluid slag and metal, respectively, will have to as cend through these pipes in order to flow over their extremities.

It is understood that the metal flowing from the bottom of the pot U through the pipe P will be pure bullion, composed of the mixed metals which may be contained in the ore. This may be sold in the market as such, or separated and refined in suitable works on the ground.

My improved blastfurnace and condenser work gas-tight, condense and save .all the metallic vapors which are now lost, and which endanger the lives and health of the workmen.

I do not claim, broadly, the placing of a coil of pipe within the walls ofafurn'ace to heat airor steam, but the construction and location of my vertical and convoluted superheater R, h, and 9,

extending from the lower part of the boshes to the top of the cone of a blast-furi'iace, for absorbing and utilizing the waste heat of the walls of the same by returning it again, in the form of heated air, to the combustion and puddlin g chamber, for dividing-the air-blast in the middle of the superheater by means of the T h, and reducing the friction between the air and pipe one-half, and consequently the power required to force the air through it differs from said coils, and has manypther advantages and economies, being arrangedin a packing ot'sand, pulverized slag, or other suitable material between the two concentric walls of a blast-furnace, whereby the iron pipe composing the superheater is protected from the melting heat of the interior of the furnace, and from the corroding and consumingv action of sulphur and its destructive compounds generated so abundantly from the ore.

Having described the mechanism and operation of my improved furnace and apparatus for smel 'g metallic ores andsaving their products, what I claim as new and useful, and desire to secure by Letters Patent, is embraced in the following claims:

1. In combination with a suitable blower, the superheater B, arranged in the packing between the two concentric walls of the furnace, whereby the pipes constituting the superheater are heated by the furnace and are protected from the action of the sulphurousacid gas passing through the furnacewalls, said superheater consisting of two series of vertical pipes extending thewhole length of the furnace, the said series being united at the top by a T, into which the pipe g is inserted to conduct air from the blower, whereby the blast is divided, thereby lessening the friction of the air in the pipes, substantially in the manner and for the purposes shown and described.

2. In combination with a blast-furnace, one or more fire-places, I, provided with grates for burning coal and with blast-pipes for conductin g the hot-blast thereto, said fire-places open- 1 ing into the furnace at or near the top of the crucible, whereby the hot gases of combustion, together with unconsurned hydrocarbon gases and fine coal-dust, are injected into the furnace to deoxidize and smelt the metals and ores therein, substantially in the manner and for the purposes herein set forth.

3. In combination with the floor V and cast. iron crucible U of a blast-furnace, the fire place 0, having a flue, F, and uptake G, for coning the fused metal and slag from chilling in the same, substantially in the manner and for the objects herein set forth.

4. In a blast-furnace, the crucible thereof, consisting of iron lined with refractory material, whereby heat is conducted to the interior 2 5 of said crucible and leakage of metal is prevented, substantially in the manner and for, l the purposes herein shown and described.

5. The combination of the retorts lm n, provided with the feed-pipes 0, stop-cocks p, and

0 funnels q, and with the discharge-pipes p g and T and set in the bench k, with the condenser d and e, submerged in the water-tank z, and through which the condensing-flue a runs, substantially as shown and described.

3 5 6. In combination with the water-tank z,the

cooling and condensing flue a, being a continnation of the covered flue N, leading from the top of the blast-furnace, having its upper side,

stantlyheating the said crucible and preventd, wholly above the bottom of the tank and tially above the bottom and submerged in water, and partially below the bottom out of contact with water, and forming two funnelshaped' sides, which inclose two openings through the bottom of the tank, all substantially in the manner and for the purposes set forth.

boxes m h within the wall 8, the sliding doors n j, closing said boxes and passing gas-tight through the said wall, substantially in the manner and for the purposes set forth.

8. The trays l k, for receiving the condensed tion with the boxes m and h, substantially in the manner and for the purposes shown and described.

9. In combination with the sulphuric-acid chamber 11, the pipe 1;, with the pipe 10, and the retort t in the niter-furuace b substantially in the manner and for the purposes hereinbefore set forth.

10. In combination with 0, leading into the sulphuric-acid chamber 1), the air-pipe '0, having an inlet-pipe, z, the steam-pipe w, ending in m, and the nitric-acid-fume pipe u within the latter, whereby a mixture of air, steam, and 'nitricacid vapor is injected, in conjunction, into the sulphuric-acid chamber p, substantially in the manner and for the objects indicated and explained.

HENRY W. ADAMS.

Witnesses Jon: E. BURROUGHS,

CHARLES BORLAND.

7. In combination with the funnel-shaped metallic fumes and other matters, in combina-- submerged in it, audits under side, 6, par- 40 

